毛乌素沙地臭柏、油蒿细根生产动态及影响因子

在毛乌素沙地开发整治研究中心北试实验地选取了七块样地,并依据建群植被外貌特征划分为臭柏群落、臭柏灌丛、油蒿群落三类。用根钻对各样地一个生长季内的根系进行了五次取样,同时测量土壤水分、枝条生长长度、温湿度等一些气象因子。对活细根分级并称干重,发现臭柏、油蒿不同径级细根的季节动态不同,不同土层内相同径级的细根生产动态也不相同:①臭柏与油蒿D≤2 mm的细根生物量在4~5月份都有一个快速增长的阶段,随后增长格局各不相同。②臭柏灌丛中,1 mm相似文献   

探地雷达树木根系定位与直径估算

针对树木根系的探地雷达(Ground Penetrating Radar,GPR)检测图像复杂、解译困难、自动化程度低且精度不高等问题,该研究提出了一种基于YOLOv3的树根自动识别和参数估计的方法。通过不同的根预埋试验分析了根直径、掩埋深度和朝向对根系识别和预测的影响,对比评估了在复杂现场环境下该方法与商业软件常用的阈值分割方法的识别效果。结果表明算法可实现根系自动提取和双曲线顶点定位,对根双曲线的识别准确率和召回率分别达到了96.62%和86.94%,根系参数预测的总平均相对误差在10.57%以内。该方法具有较高的识别准确率和鲁棒性,可实时地对树木根系进行检测并进行根系参数预测,对树木根系无损检测具有重要意义。     

南瓜饲养榕树粉蚧的发育历期与生物学特征初报

榕树粉蚧是一种重要的入侵害虫,对果蔬和园林植物存在巨大的潜在威胁.为满足开展检疫处理、防控、生物学和生理学等研究的需要,本研究以南瓜为饲养材料,在室温条件下(26±1℃,RH 65％±5％)观察榕树粉蚧的生物学特性与发育历期.结果 表明,榕树粉蚧具有典型的雌雄二型现象.雄虫主要经历卵、1～2龄若虫、预蛹、蛹、雄成虫阶段...     

生物炭对盐碱条件下海滨锦葵根系与土壤特性的影响

为探索生物炭对盐碱条件下植物根系与土壤特性的影响,以海滨锦葵为材料,在盐碱土壤中添加不同含量的生物炭,测定植株根系活力、根系生长、土壤pH值、土壤电导率、土壤容重、土壤孔隙度等指标。结果显示:在盐碱胁迫下,添加生物炭提高了海滨锦葵根系活力,中高浓度生物炭明显促进植株根系生长,土壤pH值与电导率均降低,土壤容重呈上升趋势,而土壤孔隙度呈现下降趋势。经比较,5.0%和7.5%生物炭对盐碱条件下海滨锦葵根系发育与土壤特性的调控效果相对较好。     

生草栽培果园根系生长动态研究

通过对金太阳杏生草(紫花苜蓿)栽培与生长动态的研究表明,金太阳杏新根在1年中有2次明显的生长高峰,1次是在3～4月,占全年的37%以上,第二次在6月中下旬至7月上旬。而紫花苜蓿主要在7月中旬以后,两者在时间尺度也存在有差异,根据金太阳杏新根周年变化特点,掌握2个时期,即3月中旬和6月上中旬。     

黄土丘陵沟壑区退耕年限对根—土复合体抗剪强度的影响

"退耕还林(草)"工程的有效实施,导致黄土高原植被迅速恢复,势必会引起植物根系和土壤理化性质变化,影响根—土复合体抗剪强度。为探究植被恢复年限对根—土复合体抗剪强度的潜在影响,在陕西省安塞区纸坊沟小流域选择6个不同退耕年限(5,12,20,27,37,46年)的撂荒地和1个坡耕地,进行不同土层深度(0—10,10—20,20—30,30—40,40—50 cm)根—土复合体原位剪切试验,同时测定根系特性和土壤理化性质。结果表明,随着退耕年限增加,0—50 cm土层根—土复合体抗剪强度均值呈"S"形增大趋势(51.80～124.01 J/m~2),与坡耕地相比,抗剪强度依次增加2.5%,54.6%,48.7%,86.5%,139.4%和129.3%。除坡耕地外,随着土层深度增加,根系密度明显减少,根—土复合体抗剪强度逐渐下降。根—土复合体抗剪强度与土壤有机质含量、根长密度和根质量密度呈对数正相关关系,与团聚体稳定性和有效根密度呈线性正相关关系。通径分析表明,团聚体稳定性、根质量密度和有机质含量是影响根—土复合体抗剪强度的关键因素。研究结果为评估植被恢复的水土保持效益及生态服务功能、揭示根—土复合体抗剪强度随退耕年限变化的动力机制提供理论基础。     

植物根系对土壤团聚体形成作用机制研究回顾

土壤团聚体是土壤结构的基本单元,土壤水力侵蚀的微观描述即为土壤团聚体的破裂过程。研究表明:植物根系可以改变土壤的力学以及水文特征,促进土壤团聚体的形成和稳定。因此,对近20年国内外的相关研究成果进行较为系统的回顾,从根系对土壤团聚体的物理、生物、电化学作用3个研究视角,分析了植物根系对土壤团聚体形成的作用机制,提出了现有研究中存在的问题及研究趋势,这对深入认识植物根系对土壤团聚体的影响及其作用机制、发展根-土相互作用的土壤侵蚀过程模型具有重要的意义。     

Modern wheat cultivars have greater root nitrogen uptake efficiency than old cultivars

The availability of nitrogen (N) contained in crop residues for a following crop may vary with cultivar, depending on root traits and the interaction between roots and soil. We used a pot experiment to investigate the effects of six spring wheat (Triticum aestivum L.) cultivars (three old varieties introduced before mid last century and three modern varieties) and N fertilization on the ability of wheat to acquire N from maize (Zea mays L.) straw added to soil. Wheat was grown in a soil where ¹⁵N‐labeled maize straw had been incorporated with or without N fertilization. Higher grain yield in three modern and one old cultivar was ascribed to preferred allocation of photosynthate to aboveground plant parts and from vegetative organs to grains. Root biomass, root length density and root surface area were all smaller in modern than in old cultivars at both anthesis and maturity. Root mean diameter was generally similar between modern and old cultivars at anthesis but was greater in modern than in old cultivars at maturity. There were cultivar differences in N uptake from incorporated maize straw and the other N sources (soil and fertilizer). However, these differences were not related to variation in the measured root parameters among the six cultivars. At anthesis, total N uptake efficiencies by roots (total N uptake per root weight or root length) were greater in modern than in old cultivars within each fertilization level. At maturity, averaged over fertilization levels, the total N uptake efficiencies by roots were 292?336 mg N g^?1 roots or 3.2?4.0 mg N m^?1 roots for three modern cultivars, in contrast to 132?213 mg N g^?1 roots or 0.93?1.6 mg N m^?1 roots for three old cultivars. Fertilization enhanced the utilization of N from maize straw by all cultivars, but root N uptake efficiencies were less affected. We concluded that modern spring wheat cultivars had higher root N uptake efficiency than old cultivars.     

植物根系对土壤水力参数影响的定量研究综述

植物根系是土壤结构以及土壤水力参数变化的重要影响要素。目前不仅缺乏定量描述“根-孔隙-土壤水力参数”相互作用的研究方法,在更大尺度上根系作用的客观表达也尚不明确,由此导致降雨入渗、径流和蒸发等流域水文过程的精细刻画与模拟预测具有很大的不确定性。基于文献检索,本文对国内外相关研究进行了回顾与梳理,量化了植物根系对土壤水力参数的改变和影响,并提出其与植被、土壤类型的响应方式,总结了植物根系动态性生长下的土壤水力参数定量表述及其预测模型进展。同时分析了在定量研究根-土复合系统中存在的问题及未来研究的发展方向,指出目前根系影响土壤水力参数的研究主要集中在小尺度控制实验方面,忽略了大尺度下土壤空间异质性及外部环境因素的干扰,强调大尺度根系作用和根系参数纳入土壤结构的重要性和实际意义,进一步与水文模型的深度耦合逐渐成为未来研究的热点。     

Effect of Arbuscular Mycorrhizal Fungi and Phosphate-Solubilizing Bacteria Consortia Associated with Phospho-Compost on Phosphorus Solubilization and Growth of Tomato Seedlings (Solanum lycopersicum L.)

ABSTRACT

The exploitation of phosphate mines generates an important quantity of phosphate sludge that remains accumulated and not valorized. In this context, composting with organic matter and rhizospheric microorganisms offers an interesting alternative and that is more sustainable for agriculture. This work aims to investigate the synergetic effect of arbuscular mycorrhizal fungi (AMF), phosphate-solubilizing bacteria (PSB) and phospho-compost (PC), produced from phosphate-laundered sludge and organic wastes, and their combination on plant growth, phosphorus solubilization and phosphatase activities (alkaline and acid). Inoculated mycorrhizae and bacteria strains used in this study were selected from plant rhizosphere grown on phosphate-laundered sludge. Significant (p < .05) increases in plant growth was observed when inoculated with both consortia and PC (PC+ PSB+ AMF) similar to those recorded in plants amended with chemical fertilizer. Tripartite inoculated tomato had a significantly (p < .05) higher shoot height; shoot and root dry weight, root colonization and available P content, than the control. Co-inoculation with PC and AMF greatly increased alkaline phosphatase activity and the rate of mycorrhizal intensity. We conclude that PC and endophytic AMF and PSB consortia contribute to a tripartite inoculation in tomato seedlings and are coordinately involved in plant growth and phosphorus solubilization. These results open up promising prospects for using formulate phospho-compost enriched with phosphorus-solubilizing microorganisms (PSM) in crop cultivation as biofertilizers to solve problems of phosphate-laundered sludge accumulation.